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Computer Network and Communication
SKR 3200
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Learning Outcome
• Show how to detect an error (P2)
• Show how the errors being corrected (P2)
• Explain the method being used to detect and corrected the errors (A3)
Contents
• Types of Error– Single bit error– Burst error
• Error Detection– Parity Check– CRC– Checksum
• Error Correction– Hamming Code
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Types of Errors
Single bit error – only one bit is changed from 1 to 0 or from 0 to 1.
Burst error – two or more bits in the data unit have changed.
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Error Detection Error detection uses the concepts of redundancy, which
means adding extra bits detecting errors at the destination.
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(normally implemented in link layer)
(used primarily by
upper layers)
3 common error detection techniques
Parity Check
Cyclic Redundancy Check (CRC)
Checksum
(most basic)
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Parity Check Simplest technique. A redundant bit (parity bit), is appended to every data
unit. Even parity - the total number of 1's in the data plus
parity bit must be an even number. VRC – Vertical Redundancy Check
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Data #1's in data P Total # 1's (data and P) 0110110 4 (Even) 0 4 (Even) 0011111 5 (Odd) 1 6 (Even) 0000000 0 (Even) 0 0 (Even) 1010100 3 (Odd) 1 4 (Even) 1111111 7 (Odd) 1 8 (Even)
Even Parity Generator
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Example 1Example 1
Even Parity
Suppose the sender wants to send the word world. In ASCII the five characters are coded as
1110111 1101111 1110010 1101100 1100100
The following shows the actual bits sent
11101110 11011110 11100100 11011000 11001001
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Example 2Example 2
Even Parity
Now suppose the word world in Example 1 is received by the receiver without being corrupted in transmission.
11101110 11011110 11100100 11011000 11001001
The receiver counts the 1s in each character and comes up with even numbers (6, 6, 4, 4, 4). The data are accepted.
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Example 3Example 3
Even Parity
Now suppose the word world in Example 1 is corrupted during transmission.
11111110 11011110 11101100 11011000 11001001
The receiver counts the 1s in each character and comes up with even and odd numbers (7, 6, 5, 4, 4). The receiver knows that the data are corrupted, discards them, and asks for retransmission.
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CRC
The most powerful of the redundancy checking technique.
Based on binary division. The redundancy bits used by CRC are derived by
dividing the data unit by a predetermined divisor; the remainder is the CRC.
A CRC must: have exactly one less bit than the divisor appending it to the end of the data string must make
the resulting bit sequence exactly divisible by the divisor. 13
CRC generator and checker
1. Get the raw frame.2. Left shift the raw frame by n bits
and divide it by divisor.3. The remainder is the CRC bit.4. Append the CRC bit to the frame
and transmit.
1. Receive the frame.2. Divide it by divisor.3. Check the remainder.
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Division in CRC encoder
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Division in the CRC decoder for two cases
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CRC generator – at the sending node. CRC checker – at the receiving node. Polynomial:
The CRC generator (the divisor) is most often represented as an algebraic polynomial.
e.g.
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A polynomial representing a divisor
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Standard polynomialsStandard polynomials
Name Polynomial Application
CRC-8CRC-8 x8 + x2 + x + 1 ATM header
CRC-10CRC-10 x10 + x9 + x5 + x4 + x 2 + 1 ATM AAL
ITU-16ITU-16 x16 + x12 + x5 + 1 HDLC
ITU-32ITU-32x32 + x26 + x23 + x22 + x16 + x12 + x11 + x10 + x8 +
x7 + x5 + x4 + x2 + x + 1LANs
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Checksum The error detection used by the higher-layer
protocols. Check generator – in the sending node Checksum checker – at receiving node SFD – Start Frame Delimiter FCS – Frame Check Sequence
Ethernet frame 20
Data unit and checksum
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Example 6Example 6
Suppose the following block of 16 bits is to be sent using a checksum of 8 bits.
10101001 00111001
The numbers are added using one’s complement
10101001
00111001 ------------Sum 11100010
Checksum 00011101
The pattern sent is 10101001 00111001 0001110122
Example 7Example 7Now suppose the receiver receives the pattern sent in Example 6 and there is no error.
10101001 00111001 00011101
When the receiver adds the three sections, it will get all 1s, which, after complementing, is all 0s and shows that there is no error.
10101001
00111001
00011101
------------
Sum 11111111
Complement 00000000 means that the pattern is OK.
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Example 8Example 8
Now suppose there is a burst error of length 5 that affects 4 bits.
Original data 10101001 00111001 00011101
Corrupted data 10101111 11111001 00011101
When the receiver adds the three sections, it gets
10101111
11111001
00011101
Partial Sum 1 11000101
Carry 1
Sum 11000110
Complement 00111001 the pattern is corrupted.24
Error Correction
Hamming Code Focus on a simple case: Single-Bit Error
Correction Use the relationship between data and
redundancy bits Developed by Richard Hamming
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Data and redundancy bitsData and redundancy bits
Number ofdata bits
m
Number of redundancy bits
r
Total bits
m + r
11 2 3
22 3 5
33 3 6
44 3 7
55 4 9
66 4 10
77 4 11
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Positions of redundancy bits in Hamming code (11,7)
* Check bits occupy positions that are powers of 2
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• All bit positions that are powers of 2 are used as parity bits. (positions 1, 2, 4, 8…)
• All other bit positions are for the data to be encoded. (positions 3, 5, 6, 7, 9, 10, 11…)
• Each parity bit calculates the parity for some of the bits in the code word. The position of the parity bit determines the sequence of bits that it alternately checks and skips.
• General rule for position n: skip n−1 bits, check n bits, skip n bits, check n bits...
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• Position 1 (n=1): skip 0 bit (0=n−1), check 1 bit (n), skip 1 bit (n), check 1 bit (n), skip 1 bit (n), etc. (1,3,5,7,9,11...)
• Position 2 (n=2): skip 1 bit (1=n−1), check 2 bits (n), skip 2 bits (n), check 2 bits (n), skip 2 bits (n), etc. (2,3,6,7,10,11...)
• Position 4 (n=4): skip 3 bits (3=n−1), check 4 bits (n), skip 4 bits (n), check 4 bits (n), skip 4 bits (n), etc. (4,5,6,7,12...)
• Position 8 (n=8): skip 7 bits (7=n−1), check 8 bits (n), skip 8 bits (n), check 8 bits (n), skip 8 bits (n), etc. (8-15,24-31,40-47,...)
Redundancy bits calculation
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Example of redundancy bit calculation
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Single-Bit Error
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Error Detection
Error detection using Hamming code
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